«ÉÏһƪ/Previous Article|±¾ÆÚĿ¼/Table of Contents|ÏÂһƪ/Next Article»

¡¶½¨Öþ¿ÆѧÓ빤³Ìѧ±¨¡·[ISSN:1673-2049/CN:61-1442/TU]

¾í:

36¾í

ÆÚÊý:

2019Äê03ÆÚ

Ò³Âë:

28-36

À¸Ä¿:

³ö°æÈÕÆÚ:

2019-05-22

ÎÄÕÂÐÅÏ¢/Info

Title:

Experimental Study on Bending Capacity and Calculation Method of Ultra-high Performance Concrete Slab

ÎÄÕ±àºÅ:

1673-2049(2019)03-0028-09

×÷Õß:

»Æ¸£ÔÆ^1,2,³ÂººÂ×^1,2,Ñî·¼·¼^1,2,ÁÖ ³±^1,2,³Â±¦´º^1,2

(1. ¸£ÖÝ´óѧ ¸£½¨Ê¡ÍÁľ¹¤³Ì¶àÔÖº¦·ÀÖÎÖصãʵÑéÊÒ,¸£½¨ ¸£ÖÝ 350108; 2. ¸£ÖÝ´óѧ ÍÁľ¹¤³ÌѧԺ,¸£½¨ ¸£ÖÝ 350108)

Author(s):

HUANG Fu-yun^1,2, CHEN Han-lun^1,2, YANG Fang-fang^1,2, LIN Chao^1,2, CHEN Bao-chun^1,2

(1. Fujian Key Laboratory on Multi-disasters Prevention and Mitigation in Civil Engineering, Fuzhou University, Fuzhou 350108, Fujian, China; 2. College of Civil Engineering, Fuzhou University, Fuzhou 350108, Fujian, China)

¹Ø¼ü´Ê:

³¬¸ßÐÔÄÜ»ìÄýÍÁ;  ÏËά»ìÄýÍÁ°å;  ÊÜÍä³ÐÔØÄÜÁ¦;  ²ÎÊý·ÖÎö

Keywords:

ultra-high performance concrete;  fiber concrete slab;  bending bearing capacity;  parametric analysis

·ÖÀàºÅ:

TU473

DOI:

-

ÎÄÏ×±êÖ¾Âë:

A

ÕªÒª:

ΪÍƽø³¬¸ßÐÔÄÜ»ìÄýÍÁ(UHPC)°åÔÚÖйúʵ¼Ê¹¤³ÌÖеÄÓ¦ÓÃ,¶ÔÎÞÅä½îµÄUHPC°åºÍÆÕͨ¸Ö½î»ìÄýÍÁ°å½øÐÐÁË¿¹Íä³ÐÔØÄÜÁ¦ÊÔÑé,·ÖÎöÁËUHPC°åµÄ³ÐÔØÄÜÁ¦,²¢½«ÆäÓëͬµÈ¼¶µÄ¸Ö½î»ìÄýÍÁ°å½øÐбȽϡ£½á¹û±íÃ÷:UHPC°åµÄÆÆ»µ¹ý³Ì¿É·ÖΪµ¯ÐÔ¡¢Çü·þºÍÆÆ»µ3¸ö½×¶Î,¿É½«°åµÄ×î´óÁÑ·ì¿í¶È´ï0.1 mmʱµÄºÉÔØÊÓΪUHPC°åµÄÁÑ·ìºÉÔØ; UHPC°åµÄÊÜÍäÆÆ»µÊôÓÚÑÓÐÔÆÆ»µ,Âú×ãʵ¼Ê¹¤³ÌµÄÐèÇó; UHPC°åµ¯ÐÔ¼«ÏÞºÉÔØÊÇͬµÈ¼¶¸Ö½î»ìÄýÍÁ¸Ç°åµÄ220%,¼´UHPC°åµÄ¿¹ÁÑÄÜÁ¦Ç¿,ÔÚ³£¹æºÉÔØ×÷ÓÃÏÂÓµÓиüºÃµÄÄ;ÃÐÔºÍÊÊÓÃÐÔ; ÆÕͨ¸Ö½î»ìÄýÍÁ°å³ÐÔØÆÆ»µÊ±,ͬµÈ¼¶µÄUHPC°åÒÀÈ»¿ÉÒÔÕý³£¹¤×÷ÇÒÓнϴó³ÐÔØÄÜÁ¦¸»Óà,ÔÚ³ÐÔØÄÜÁ¦·½ÃæUHPC°åÍêÈ«¿ÉÒÔÌæ´úÆÕͨ¸Ö½î»ìÄýÍÁ°å; ͬʱ,¸ù¾ÝÓÐÏÞÔª²ÎÊý·ÖÎö½á¹û,½¨Òéʵ¼Ê¹¤³ÌÖÐUHPC°å¸÷²ÎÊý°´ÒÔÏ·¶Î§È¡Öµ,¸ÖÏËάº¬Á¿(ÖÊÁ¿·ÖÊý)ÔÚ1.5%¡«2.5%Ö®¼ä,ºñ¶ÈÔÚ30¡«50 mmÖ®¼ä,²ÄÁϵȼ¶ÔÚU120¡«U160Ö®¼ä; ¸ø³öµÄ¼ÆËãÎÞÅä½îUHPC°åÕý½ØÃæÊÜÍä³ÐÔØÁ¦¼ò»¯¼ÆË㹫ʽ¾ßÓнϺõľ«¶È,¿ÉΪ¹¤³Ìʵ¼ÊÓëÏà¹Ø¹æ·¶µÄÖƶ¨Ìṩһ¶¨²Î¿¼¡£

Abstract:

To promote the practical application of ultra-high performance concrete(UHPC)slab in China, the bending bearing capacity of UHPC slab and ordinary reinforced concrete slab were tested, the bearing capacity of UHPC slab from several aspects was analyzed, and the results were compared with those of the same grade traditional one. The results indicate that the failure process of UHPC slab can be divided into elastic stage yield stage and failure stage, when the maximum crack is 0.1 mm, the load can be considered as the crack load. The bending failure process of UHPC slab is ductile failure, which meets the needs of practical engineering. The ultimate elastic load of UHPC slab is 220% of that of the same grade reinforced concrete slab, that is, the crack resistance and bearing capacity of UHPC slab are better than those of traditional one, and UHPC slab has better durability and applicability under the conventional load. The UHPC slab can still work normally when the ordinary reinforced concrete slab is destroyed, UHPC slab can completely replace the ordinary reinforced concrete slab in bearing capacity. The parameter analysis results from the finite element simulation indicate: it¡¯s better to control the content of steel fiber(mass fraction)between 1.5%-2.5%, the thickness is between 30-50 mm, the materials grade is between U120-U160. The simplified formula for calculating the bending bearing capacity of the UHPC slab has a good precision, which can provide a reference for the engineering practice and the relevant specifications.

²Î¿¼ÎÄÏ×/References:

[1] ³Â±¦´º,¼¾ èº,»ÆÇäά,µÈ.³¬¸ßÐÔÄÜ»ìÄýÍÁÑо¿×ÛÊö[J].½¨Öþ¿ÆѧÓ빤³Ìѧ±¨,2014,31(3):1-24.
CHEN Bao-chun,JI Tao,HUANG Qing-wei,et al.Review of Research on Ultra-high Performance Concrete[J].Journal of Architecture and Civil Engineering,2014,31(3):1-24.
[2]DE LARRARD F,SEDRAN T.Optimization of Ultra-high-performance Concrete by the Use of a Packing Model[J].Cement and Concrete Research,1994,24(6):997-1009.
[3]AYDIN S,BARADAN B.Engineering Properties of Reactive Powder Concrete Without Portland Cement[J].ACI Materials Journal,2013,110(6):619-627.
[4]°½³¤½­.Ìú·ÇÅÁºÓûîÐÔ·ÛÄ©»ìÄýÍÁÈËÐеÀ°å¼°Ö§¼ÜµÄÖÆÔ칤ÒÕ¼¼Êõ[J].ÁÖÒµ¿Æ¼¼Ç鱨,2004,39(4):66-67,69.
AO Chang-jiang.Produce Technique of Activated Dust Concrete Footpath Board and Bracket Used in Railway Bridge[J].Journal of Forest Science and Technology Information,2004,39(4):66-67,69.
[5]Íõ Ç«,ÁõÓÀ±ò,³ͳÎÀ.RPC150µÄÐÔÄܼ°ÔÚ¸ßÌú¹¤³ÌÖÐÓ¦ÓÃ[J].µÍν¨Öþ¼¼Êõ,2012,34(8):13-15.
WANG Qian,LIU Yong-bin,LU Tong-wei.Performance and Application of RPC150 in HSR Engineering[J].Low Temperature Architecture Technology,2012,34(8):13-15.
[6]ʯ ÀÚ.RPC130 »îÐÔ·ÛÄ©»ìÄýÍÁÔÚʯÎä¿ÍרÌú·¹¤³Ì¸Ç°åÉú²úÖеÄÓ¦ÓÃÑо¿[J].ÌúµÀ½¨Öþ,2011(5):134-135.
SHI Lei.The Application of RPC130 in the Production of Railway Engineering Cover Plate in Shiwuke[J].Railway Engineering,2011(5):134-135.
[7]Àî Ôª,Íõ ¶¬,춶¨ÐÂ.ÔçÇ¿Ð;ÛôÈËá¼õË®¼ÁÔÚ¿ÍÔËרÏßRPC(»îÐÔ·ÛÄ©»ìÄýÍÁ)¸Ç°å¹¤³ÌÖеÄÓ¦ÓÃ[J].ÉÌÆ·»ìÄýÍÁ,2011(5):62-63.
LI Yuan,WANG Dong,YU Ding-xin.The Application of Early Strength Polycarboxylic Acid Reducer in the Construction of the Passenger Dedicated Line RPC[J].Ready-mixed Concrete,2011(5):62-63.
[8]³£ Çà.ÑϺ®µØÇø¸ßËÙÌú·RPC-130»îÐÔ·ÛÄ©»ìÄýÍÁ²ÄÁÏÓ¦ÓÃ[J].Öйú½¨²Ä¿Æ¼¼,2014(1):38-39,47.
CHANG Qing.High Speed Railway RPC-130 Reactive Powder Concrete Material Application[J].China Building Materials Science & Technology,2014(1):38-39,47.
[9]ÕÔ Âü,ÑÖ¹óƽ,ºÂÎÄÐã.¸ßËÙÌú·RPC¸ñ¹¹Ð͹ìµÀ°åµÄÉè¼ÆÓë·ÂÕæ·ÖÎö[J].±±¾©½»Í¨´óѧѧ±¨,2008,32(1):64-68.
ZHAO Man,YAN Gui-ping,HAO Wen-xiu.Simulation Analysis and Design of RPC Lattice Slab in High-speed Railway[J].Journal of Beijing Jiaotong University,2008,32(1):64-68.
[10]»ÆÐñÒã,Îâ ΰ.RPC¸Ç°å³ÐÔØÁ¦Ó뿹ÁÑÐÔÊÔÑéÑо¿[J].ÔÆÄÏË®Á¦·¢µç,2013,29(3):15-18.
HUANG Xu-yi,WU Wei.The Test and Study of RPC Capping Plate Bearing Capacity and Crack Resistance[J].Yunnan Water Power,2013,29(3):15-18.
[11]YANG J,WANG J S,PENG X.Design and Behavior of RPC Slab Track[J].Applied Mechanics and Materials,2014,587/588/589:1100-1105.
[12]ZHENG W,LU X,YING W.Flexural Behaviour of Precast,Prestressed Ribbed RPC Bottom Panels[J].Open Civil Engineering Journal,2015,9(1):98-106.
[13]³Âºêΰ,¹ù Ãô,ÕÔºêÖ¾,µÈ.RPC¸Ç°å¿¹Íä³ÐÔØÁ¦ÊÔÑéÑо¿[J].ÌØÖֽṹ,2016,33(5):23-27.
CHEN Hong-wei,GUO Min,ZHAO Hong-zhi,et al.Experimental Study on Flexural Behavior of RPC Cover Slabs[J].Journal of Special Structures,2016,33(5):23-27.
[14]MAHMOOD M,DAWOOD M.Flexural Behavior of Continuous Bubbled Reinforced Reactive Powder Concrete Flat Slab[J].Journal of Babylon University,2017,25(2):504-505.
[15]Q/CR 2.1¡ª2014,ÌúµÀµçÀ²۸ǰåºÍÈËÐеÀ²½°å µÚ1²¿·Ö:»îÐÔ·ÛÄ©»ìÄýÍÁÐÍ[S].
Q/CR 2.1¡ª2014,Railway Cable Trough Cover Plate and Sidewalk Step Plate ¡ª Part 1:Reactive Powder Concrete[S].
[16]GB 50010¡ª2010,»ìÄýÍÁ½á¹¹Éè¼Æ¹æ·¶[S].
GB 50010¡ª2010,Code for Design of Concrete Structures[S].
[17]GB/T 31387¡ª2015,»îÐÔ·ÛÄ©»ìÄýÍÁ[S].
GB/T 31387¡ª2015,Reactive Powder Concrete[S].
[18]Çñ¼ÌÉú.¸ÖÏËά»ìÄýÍÁ½á¹¹·ÇÏßÐÔÓÐÏÞÔª·ÖÎö·½·¨Ñо¿[J].»ìÄýÍÁ,2011(3):17-20,24.
QIU Ji-sheng.Study on Nonlinear Finite Element Analysis of Steel Fiber Concrete Structure[J].Concrete,2011(3):17-20,24.
[19]ALGUHI H A,ELSAIGH W A.Development of Tensile Stress-strain Relationship for High-strength Steel Fiber Reinforced Concrete[J].International Journal of Civil,Environmental,Structural,Construction and Architectural Engineering,2016,10(2):190-196.
[20]Õžüΰ,¸ßµ¤Ó¯,Ö캣ÌÃ.¸Ö½î¸ÖÏËά»ìÄýÍÁÅ£ÍÈ¿¹ÁÑÐÔÄÜÓÐÏÞÔª·ÖÎö[J].Ö£ÖÝ´óѧѧ±¨:¹¤Ñ§°æ,2009,30(4):1-5.
ZHANG Jun-wei,GAO Dan-ying,ZHU Hai-tang.Nonlinear Finite Element Analysis on Cracking-resistance Behaviors of Steel Fiber Reinforced Concrete Corbels[J].Journal of Zhengzhou University:Engineering Science,2009,30(4):1-5.
[21]AFGC/SETRA 2013,Ultra High Performance Fibre Reinforced Concretes[S].
[22]Concrete Engineering Series 82,Recommendations for Design and Construction of High Performance Fiber Reinforced Cement Composites with Multiple Fine Cracks(HPFRCC)[S].
[23]MANSUR M A,CHIN M S,WEE T H.Stress-strain Relationship of High-strength Fiber Concrete in Compression[J].Journal of Materials in Civil Engineering,1999,11(1):21-29.
[24]¹ÜÆ·Îä,Ìƹú±ó,ÃÏ»áÓ¢.¸ÖÏËά»ìÄýÍÁ¹µ¸Ç°å³ÐÔØÄÜÁ¦ÊÔÑéÑо¿[J].»ìÄýÍÁÓëË®ÄàÖÆÆ·,2006(5):49-51.
GUAN Pin-wu,TANG Guo-bin,MENG Hui-ying.Study on Carrying Capacity of Steel Fiber Reinforced Concrete Trench Cover Plate[J].China Concrete and Cement Products,2006(5):49-51.

ÏàËÆÎÄÏ×/References:

[1]³Â±¦´º,¼¾èº,»ÆÇäά,µÈ.³¬¸ßÐÔÄÜ»ìÄýÍÁÑо¿×ÛÊö[J].½¨Öþ¿ÆѧÓ빤³Ìѧ±¨,2014,31(03):1.
¡¡CHEN Bao-chun,JI Tao,HUANG Qing-wei,et al.Review of Research on Ultraª²high Performance Concrete[J].Journal of Architecture and Civil Engineering,2014,31(03):1.
[2]ÉÛÐñ¶«,²Ü¾ý»Ô.ÃæÏòδÀ´µÄ¸ßÐÔÄÜÇÅÁº½á¹¹Ñз¢ÓëÓ¦ÓÃ[J].½¨Öþ¿ÆѧÓ빤³Ìѧ±¨,2017,34(05):41.
¡¡SHAO Xu-dong,CAO Jun-hui.Research and Application of High Performance Bridge Structures Toward Future[J].Journal of Architecture and Civil Engineering,2017,34(03):41.
[3]·½ Ö¾,Ö£ »Ô,Ñî ½£,µÈ.³¬¸ßÐÔÄÜ»ìÄýÍÁ½á¹¹µÄÉè¼Æ·½·¨[J].½¨Öþ¿ÆѧÓ빤³Ìѧ±¨,2017,34(05):59.
¡¡FANG Zhi,ZHENG Hui,YANG Jian,et al.Design Principles for Ultra-high Performance Concrete Structures[J].Journal of Architecture and Civil Engineering,2017,34(03):59.
[4]ÀîÁ¢·å,·¶ ê¿,ʯÐÛΰ,µÈ.Ô¤Ó¦Á¦UHPCÁºÍäÇúÐÔÄÜ·ÖÎöÓëºÏÀíÉè¼Æ[J].½¨Öþ¿ÆѧÓ빤³Ìѧ±¨,2018,35(02):38.
¡¡LI Li-feng,FAN Xin,SHI Xiong-wei,et al.Analysis of Flexural Performance and Rational Design of Prestressed UHPC Beam[J].Journal of Architecture and Civil Engineering,2018,35(03):38.
[5]³Â±¦´º,Τ½¨¸Õ,ËÕ¼ÒÕ½,µÈ.³¬¸ßÐÔÄÜ»ìÄýÍÁÓ¦ÓýøÕ¹[J].½¨Öþ¿ÆѧÓ빤³Ìѧ±¨,2019,36(02):10.
¡¡CHEN Bao-chun,WEI Jian-gang,SU Jia-zhan,et al.State-of-the-art Progress on Application of Ultra-high Performance Concrete[J].Journal of Architecture and Civil Engineering,2019,36(03):10.
[6]Ðì ¸Û,Îij¤³Ç,Íõ Çà,µÈ.³¬¸ßÐÔÄÜ»ìÄýÍÁ±£»¤²ãºñ¶ÈÈ¡Öµ·ÖÎö[J].½¨Öþ¿ÆѧÓ빤³Ìѧ±¨,2023,40(05):32.[doi:10.19815/j.jace.2022.01015]
¡¡XU Gang,WEN Changcheng,WANG Qing,et al.Value analysis of UHPC cover thickness[J].Journal of Architecture and Civil Engineering,2023,40(03):32.[doi:10.19815/j.jace.2022.01015]

±¸×¢/Memo

±¸×¢/Memo:

ÊÕ¸åÈÕÆÚ:2018-10-09
»ù½ðÏîÄ¿:¹ú¼Ò×ÔÈ»¿Æѧ»ù½ðÏîÄ¿(51578161,U1305245); ¸£ÖÝÊпƼ¼Ö§³Ö¼Æ»®²úѧÑÐÏîÄ¿(2018-G-63)
×÷Õß¼ò½é:»Æ¸£ÔÆ(1979-),ÄÐ,½­Î÷·á³ÇÈË,Ñо¿Ô±,¹¤Ñ§²©Ê¿,E-mail:huangfuyun@fzu.edu.cn¡£

³£Óù¦ÄÜ

¸üÐÂÈÕÆÚ/Last Update: 2019-05-23